Flask with resiliently yieldable mold retaining member



R. OLSON 3,513,905

FLASK WITH RESILIENTLY YIELDABLE MOLD RETAINING MEMBER May 26, 1970 Original Filed June 8, 1966 INVENTOR izafidl. Q5502? United States Patent 3,513,905 FLASK WITH RESILIENTLY YIELDABLE MOLD RETAINING MEMBER Richard L. Olson, Hickory Hills, 111., assignor to Dike-O- Seal, Incorporated, Chicago, 111., a corporation of Illinois Original application June 8, 1966, Ser. No. 556,193, now Patent No. 3,429,360, dated Feb. 25, 1969. Divided and this application Sept. 3, 1968, Ser. No. 777,532

Int. Cl. B22c 21/14 US. Cl. 164-380 7 Claims ABSTRACT OF THE DISCLOSURE A slip flask for foundry sand molding wherein the smooth inner wall surfaces of the flask are provided with recess areas containing resiliently yieldable mold retaining members. The retaining members are bonded directly and inseparably to the sides defining the recess to thereby seal the recess against entrance of sand therein. Fluid pressure is used for thrusting the retainer members into gripping engagement with the sand mold body.

This application is a division of my copending application Ser. No. 556,193, filed June 8, 1966, now Pat. No. 3,429,360 issued Feb. 25, 1969.

This invention relates to the art of preparing sand molds for use in the foundry industry, and more particularly concerns the retention of the compacted sand mold bodies in the molding flasks used for this purpose, through the steps of separating the sand mold body from the molding pattern.

A problem of major consequence in sand molding in the foundry industry has been that of retaining the molded sand body within the flask throughout the step of separating the molding pattern from the sand mold. This step generally involves lifting the flask and contained sand mold away from the pattern, but may comprise moving the pattern downwardly out of the sand mold. In any event, the sand mold must not escape from the flask until the mold, generally referred to as the cope half, has been positioned for reception by a supporting surface which may, and usually does, comprise a complementary or drag half sand mold to be paired therewith for casting purposes.

Heretofore two principal arrangements have been utilized for separating the sand molds from the flasks. One widely used arrangement comprises hingedly connecting separable portions of the flasks so that they can be opened and thus removed from the sand mold which has been retained against falling out of the flasks by means of interlocking serrations, waflle-like and other patterns of indentations in the flask wall inner surfaces. In another arrangement, sand strips are employed which are shiftably mounted intermediate the top and bottom of the flask to protrude into the sand mold interlockingly and when it is desired to discharge the mold such strips are retracted from the mold. All of these arrangements are notoriously ineflicient, require moving metal parts, are highly susceptible to damage and wear, generally add substantial dead weight to the flasks, require joints susceptible to sand exclusion and inherently have points of weakness at the joints and connections. For example, the breakaway corner mechanisms employed on the conventional hinged types of flasks are made of steel or malleable iron, or a combination thereof, and are necessarily heavy and bulky, and are costly to operate due to the manpower required, as well as costly to repair and maintain because they are exposed to sand abrasion and wear. Sand strips are also heavy and cumbersome metal pieces which are exposed to excessive Wear and erosion damage from the molding sand. Further, much time and effort is consumed in open- "ice ing and closing these strip retainers, and they are an impedance in the way of the molders when removing the flasks from the mold.

It is, accordingly, an important object of the present invention to overcome the foregoing and other problems and avoid the numerous disadvantages of the prior expedients, and to provide means for preparing sand molds entirely eliminating movable metal parts for retaining sand molds in flasks.

Another object of the invention is to provide a new means for sand molding in slip flasks according to which the sand mold bodies are retained by engagement with a resiliently yieldable retainer.

A further object of the invention is to provide a new means for retaining sand molds in flasks and utilizing air as motivating force.

Still another object of the invention is to substantially reduce the weight of foundry flasks by eliminating therefrom any need for breakaway mechanisms, sand strips or other metal mold-retaining or releasing devices, but to provide a lightweight or actually weight reducing elastomeric retaining device.

Other objects, features and advantages of the present invention will be readily apparent from the following detailed description of certain preferred embodiments thereof taken in conjunction with the accompanying drawing, in which:

FIG. 1 is a vertical diametrical section detail view through a typical foundry flask embodying features of the invention;

FIG. 2 is an enlarged fragmentary elevational view taken substantially in the plane of line II-II of FIG. 1;

FIG. 3 is an enlarged fragmentary sectional detail view of the elastomeric retainer of FIG. 1 showing the same in operation under air pressure;

FIG. 4 is a similar sectional view demonstrating a modification or at least a modified manner of using the elastomeric retainer of FIGS. 1-3;

FIG. 5 is a similar sectional view illustrating a further modification;

FIG. 6 is an elevational view of an adapter plate carrying an elastomeric mold retainer according to the present invention;

FIG. 7 is a fragmentary vertical sectional view through a foundry flask mounting the adapter plate of FIG. 6; and

FIG. 8 is a fragmentary vertical sectional view showing another form of mold retaining adapter applied to a flask.

A representative foundry flask 10, comprising a cope section, with which the present invention is adapted to be practiced is shown in FIG. 1, of the slip type comprising an upright wall 11 having upper and lower outwardly projecting reinforcing flanges 12. Any preferred external reinforcement may be provided for the wall 11. Desirably the flask 10 should be constructed as light in weight as consistent with size and service requirements including and packing pressures employed, and the material of the flask may be chosen wtih these and other various factors in mind. Further, the flask 10 desirably formed as a onepiece casting or may, if preferred, be formed of separate parts assembled together and permanently secured by welding or bolting.

Pursuant to the principles of the present invention, the flask wall 11 has its inner surfaces vertically smooth and provided with the customary downwardly flaring taper of about 4. Thereby a sand mold 14 compacted in the flask as 'by means of a squeeze plate 15, or otherwise, is in slip release engagement with the wall surfaces 13. A molding cavity 17 is formed within the sand mold body 14 by a pattern 18 mounted in customary fashion upon a pattern plate 19 against which the flask 10 rests through its lower flange 12. The pattern plate 19 may be what is commonly referred to as a match plate, carrying on its lower face a downwardly projecting pattern complementary to and arranged to form the lower half of the final mold cavity of which the cavity 17 provides the upper half. As is customary, the lower half of the mold cavity is formed in a sand body compacted within a lower flask member commonly referred to as the drag.

Immediately after packing of the sand mold body 14 has been completed, separation of the pattern 18 therefrom is effected. This is followed by placing the bottom of the sand mold body 14 against a supporting surface, which most generally comprises the top of the drag half sand mold, and the mold 14 is then discharged from the cope flask 10. In preparation for pouring of metal into the mold cavity, the joined sand molds are customarily jacketed.

According to the present invention, retention of the sand mold body 14 within the slip flask 10 while the pattern 18 is removed either by lifting the flask 10 away from the pattern or withdrawing the pattern downwardly away from the flask, as preferred, is effected without the use of any movable metal parts, such as latches, hinges, sand retainer plates, or the like, exposed to or liable to wear from the molding sand. Sand mold retention is effected by engaging the mold body with a resiliently yieldable retainer which is highly resistant to wear especially from sand abrasion; enabling free handling of the flask and sand mold as a unit and then easy and immediate release and discharge of the sand mold from the flask when desired. For this purpose, the flask 10 is provided with one or more retainers comprising a resiliently yielda'ble member 21 in or associated with the flask wall inner surface or surfaces 13. In one desirable arrangement, the elastomeric retainer member 21 is mounted within a recess molded or machined directly in the flask wall 11 and opening through the surface 13 with its opening area of suitable size and configuration to expose a desirable area of mold-confronting and engaging surface 23 of the retainer at the surface 13 (FIGS. 1-3). Although the retainer 21 may be in the form of one or more patch-like areas suitably located, a strip-form arrangement wherein the recess 22 is in the form of a groove extending in a generally horizontal direction adjacent to the lower edge of the flask wall 11 is especially eflicient. To increase the actual engaged area of the sand mold while maintaining the width of the groove and of the exposed retainer surface 23 within relatively narrow bounds, the groove and strip may be of any preferred lineal configuration. One such configuration exemplified in FIG. 2 is generally zig-zag, or generally wavy line orientation.

Means are provided for releasably retaingly engaging the retainer 21 with the sand mold body 14. One way of attaining this result is to have the retainer surface 23 normally within the plane of the flask surface 13. Then after the sand mold body '14 has been compacted air pressure is introduced behind the retainer 21 whereby to press it toward the sand body to effect frictional gripping of the surface 23 against the confronting surface of the sand mold. This desirable effect is implemented by having the retainer made from closed cell elastomeric material, or so-called bubble rubber of suitable density or compression factor. Desirably the elastomeric body of the retainer 21 is molded directly within the groove 22, with the opposite sides of the rubber body bonded directly and inseparably to the sides defining the groove while the base of the rubber retainer body comprises a surface 24 which is at least throughout its major width free from the root or base surface of the groove. Normally the closed cell elastomeric body of the retainer 21 completely fills the groove 22 with the inner or back surface 24 engaging the root surface of the groove as shown in FIG. 1 and indicated in dash outline in FIG. 3. 7

Means for thrusting the retainer 21 into retaining gripping engagement with the sand mold body 14 comprise fluid pressure introduced between the root of the groove 22 and the retainer member surface 24 through a suitable passage 25 leading thereto through the wall 11, as for example by way of the base flange 12. Pressure fluid such as air is adapted to be supplied to the passage 25 by means such as an air hose 27 coupled with the outer end of the passage and connected with a suitable air source 28 (FIG. 1) such as a compressed air tank or compressor and under the control of a suitable valve 29 by which the air is directed to the retainer as desired for effecting retaining gripping of the sand mold, or the air is bled from the retainer to release it from the sand mold when the sand mold is to be discharged from the flask. As shown in FIG. 3, during pressurizing of the retainer 21, the back surface 24 cavitates responsive to the air pressure away from the groove root surface, thereby thrusting the retainer body under substantial compressive force substantially proportionate to the air pressure toward the confronting surface of the sand body 14. In this action the bubble rubber is advantageous not only because of its ability to cavitate at the back while the friction gripping crown surface 23 of the retainer does not displace or at least displaces only slightly into conformity with the confronting surface area of the sand body 14, by virtue of the compressibility of the closed cell material, but also because as the rear surface 24 cavitates its surface area progressively increases to present a greater area to the air pressure for a concentration of inward retaining gripping pressure against the sand body, even though the sides of the rubber strip are firmly'bonded against separation from the sides defining the groove 22. To release at least these portions of the bonded sides adjacent to the back surface 24 from undue strain and to avoid danger of popout of the retainer during pressurization in an empty flask, the sidewalls of the groove 22 contiguous to the groove root are formed with undercuts 30 into which flanges 3 1 of the retainer body are molded. Thereby upon pressurization of the retainer the material in the flanges 31 is compressived toward respective opposing ledges 32 and dihedral corners 33 cooperating with the bonds of the retainer to the groove walls for effectively resisting blowout.

Although under some conditions provision of the retainer 21 in one of a number of angularly related sections of the Wall surfaces 13 may suffice, it may under other conditions be desirable to provide the retainer at a plurality of places in the wall areas of the flask, such as at diametrically opposite sides of the flask as shown in FIG. 1, where duplicate sections of the retainer 21 are provided isolated from one another but operating in opposition to grip the sand body 14 therebetween from the same air source. On the other hand, the retainer may be provided as a continuous strip 21' in a continuous groove 22 completely encircling the molding chamber within the flask. While the continuous, encircling retainer 21' may be located adjacent to the bottom of the wall 11 it may also be utilized, as shown, auxiliary to the bottom retainer structure 21 at a different, and in this instance upper location so as to afford multiple retaining gripping of the sand mold body 14 at spaced intervals along its height. Where the retainer 21' is used as an auxiliary, it may be pressurized from the same air source through a branch hose conduit 27' connected with the hose 27 by a branch connector 34.

Although pressurization of the connector 21 is adapted to be effected after compacting of the sand body 14, the arrangement may be employed as depicted in FIG. 4 wherein the retainer 21 is pressurized from the relaxed unpressurized condition depicted in dash outline to the full outline position with the mold-engaging crown surface 23 bulged into the molding chamber of the flask prior to compacting of the sand so that a substantially interlocked relation of the bulged retainer within a formed groove 35 in the mold body 14 prevails while the retainer remains pressurized. Release of the mold body is then effected by depressurizing and relaxing the retainer to move back to its normal condition as shown in dash outline wherein the surface 23 is within the plane of the flask surface 13 so that the sand body 14 can escape thereby for discharge from the flask.

For more rapid action, a negative pressure or vacuum may be applied to the inner base surface 24 of the retainer 21 for release purposes. Under such circumstances, the valve 29 may be operable to connect the hose 27 alternately to the compressed air source 28 or to a vacuum chamber or pump through a conduit 37. Under vacuum, the retainer 21 will snap into the releasing condition positively for instantaneous release of the sand mold.

In another manner of utilizing the retainer 21, as exemplified in FIG. 5, it may be constructed of a closed cell elastomer which at least in the mold-engaging portion thereof is of sufficient softness so that under the compacting pressure applied to the sand core body 14, an interlock protrusion 38 from the surface of the sand mold will compressibly intrude itself into the confronting retainer so as to be substantially interlockingly engaged therewith in the mouth of the groove 22. For this purpose the retainer member 21 may be in a relaxed, unpressurized condition or may even be under a vacuumized condition. Then, to release the sand mold 14, the mold-engaging surface 23 of the retainer member 21 is blown toward the sand mold as indicated in dash outline in FIG. to displace the interlock protrusion or bulge 38 at least to or slightly beyond the plane of the flask chamber surface 13, and the member 21 then released or relayed so that the mold 14 may be slidably dislodged and discharged from the flask.

Where instead of providing a retainer housing recess directly in the wall of the flask, it is preferred to equip the flask with the retainer as an adaptation or in a manner to enable quick replacement, the arrangement depicted in FIGS. 6 and 7 may be employed. This includes an adapter plate 39 of any preferred size dimensioned to be received in a complementary opening 40 in a wall 41 of a flask, with a surface 42 of the adapter plate smooth and flush with an inner smooth surface 43 defining the slip flask molding chamber. A lateral flange 44 on the outer portion of the adapter plate 39 is adapted to be secured fixedly but removably as by means of screws 45 to the flask wall 41. A resiliently yieldable, preferably closed cell elastomer retainer member 47 is mounted within a recess 48 in the form of a groove in the adapter plate 39 and is adapted to be pressurized and if desired vacuumized through a passage including fluid duct 49 for service in similar fashion as described in respect to the retainer member 21.

Another form of adapter as depicted in FIG. 8 com prising a frame 50 having inner smooth wall surfaces 51 which match and provide continuation of slip flask mold chamber surfaces 52 of a flask wall 53, the base flange 54 of which is mounted on and secured to the adapter frame 50 as by means of screws 55. A resiliently yieldable and preferably monocellular rubber retainer 57 is mounted in a recess groove 58 opening through the wall 51 of the adapter frame and having a fluid pressure passage 59 communicating with its back surface and adapted to be connected with a pressure source conduit hose 60 which may also be connected with a vacuum source, similarly and for the purposes described in respect to the form of FIG. 1. Operation of the retainer 58 may be the same as described for the retainer 21.

As will be apparent, the pressurized retainer may be used either on manually manipulated flasks or on flasks used in connection with automatic molding machines. In either manual or machine use of the flask substantial advantage is gained by reason of the significant reduction in weight, simplicity of structure and increased speed of operation.

While principal attention has been directed to use of the pressurizable or vacuumizable retainer with the cope flask 10 use of such retainer with the drag flask 20 is advantageous where the drag flask must be lifted from its supporting surface before the sand mold is removed therefrom. In rollover operations, for example, a retainer board or plate is customarily used, and may be dispensed with where the present retainer is employed.

It will be understood that variations and modifications may be effected without departing from the spirit and scope of the novel concepts of this invention.

I claim as my invention:

1. In sand mold preparing apparatus comprising a slip flask having smooth inner wall surfaces for compacting of a sand mold in slidably releasable relation within said wall surfaces and about a pattern, the improvement comprising:

a limited area of said inner wall surfaces having a recess provided with a bottom and sides and running out at said area;

a resiliently yieldable mold retaining member in said recess and free to move relative to said recess bottom but positively held to said sides to seal the recess against entrance of sand past said runout; and

means for thrusting said member resiliently away from said bottom into mold engaging condition thereof relative to said wall surfaces and the mold, and said means being operative to release said member to enable slipping of the mold from the flask;

whereby in said mold engaging condition of the member, the mold and the pattern are separable by relative movement of the pattern and the flask with the mold retained in the flask, and thereafter when said member is released the mold is slidably dischargeable from the flask.

2. Apparatus according to claim 1, said recess being directly in a wall of the flask and opening directly through the smooth inner surface of said wall.

3. Apparatus according to claim 1, comprising an adapter plate having said recess therein and the flask having an opening in a portion of said wall surfaces within which said plate is secured.

4. Apparatus according to claim 1, comprising an adapter frame secured to the flask and having said recess therein.

5. Apparatus according to claim 1, said resiliently yieldable member comprising a monocellular elastomeric body normally completely filling said recess and bonded to said recess sides but free from said recess bottom, and said means for thrusting said member comprising structure defining a fluid passage leading to and opening to the interfaces of said bottom and said elastomeric body and means for effecting a pressure differential through said passage.

6. Apparatus according to claim 5, said recess having undercuts contiguous to said recess bottom, and said elastomeric body having anchoring flange means thereon filling and bonded to the surfaces defining said undercuts.

7. Apparatus according to claim 1, said recess comprising a zig-zag groove in said area such that the member has a generally wavy line orientation.

References Cited UNITED STATES PATENTS 947,261 1/ 1910 Scrivenor 1643 81 3,225,396 12/1965 Hansberg 164-202 FOREIGN PATENTS 1,402,793 5/1965 France.

ROBERT D. BALDWIN, Primary Examiner US. Cl. X.R. 

